Composite powder metal variable boundary gear and method

ABSTRACT

A forged composite gear and a method of making a forged composite powder metal gear. The forged composite gear includes a plurality of teeth extending from a core, a first section having a first powder metal material, a second section having a second powder metal material and a variable boundary profile. The variable boundary profile is formed between the first section and the second section, whereby said variable boundary profile exhibits greater tooth wear resistance on the teeth and greater impact resistance in the core.

TECHNICAL FIELD

The invention relates to a forged powder metal part and more particularly to a composite powder metal variable boundary part, including a method of manufacture thereof.

BACKGROUND OF THE INVENTION

There is continuing demand for manufacturing processes that may lessen the cost, time or steps in producing a part. More often than not, the benefits resultantly associated with improving the manufacturing process are necessitated in the first instance by customer requirements to develop and improve products to have superior dimensional, mechanical and/or performance properties. For instance a typical differential side gear may have any or all of the following performance requirements such as: the spline area requiring dimensional precision, high shear strength and brinnelling resistance; the hub and thrust faces requiring dimensional precision, surface finish and case compatibility; the gear geometry requiring dimensional precision, surface finish and optimised profile; and the tooth and core strength may require impact resistance, wear resistance, spalling resistance, and different surface and core metallurgies. Different non-compatible manufacturing processes, i.e. casting, steel forging or powder metal forging, obtain different performance requirements for the same part, advantageously or otherwise.

Referring to FIG. 1, in order to meet some of these performance requirements, a gear 10 is made by forging a powder metal 14 and then case carburizing the gear to achieve a nearly constant effective case depth 16. The case depth 16 for each gear tooth 12 is shown in the partial cross-sectional view of FIG. 1. However, a case carburized gear does not necessarily achieve the desired mechanical properties such as enhanced tooth wear and fatigue strength while providing beneficial performance characteristics in the body of the gear that could beneficially result if the part was made from composite materials. It would be advantageous to achieve an improved balance of these performance requirements in the final product, uncompromised by the manufacturing process thereby saving time, processing or cost.

A manufacturing process to improve the performance requirements of powder metal parts is disclosed in U.S. Pat. No. 5,903,815 titled “Composite Powdered Metal Component.” The process teaches a component made from two or more discreet powder metals that are compacted and then sintered. Also, U.S. Pat. No. 6,148,685 titled “Duplex Sprocket/Gear Construction and Method of Making Same,” discloses a method of making a gear made from two or more discreet powder metals that are then also compacted and sintered to obtain the final part. These patents only teach composite powdered metal parts obtained by sintering, in general. No known processes exist which address applying composite powder processes to improve performance features such as improved load bearing upon the tooth flank of a gear while providing impact resistance and bending fatigue resistance in the tooth root; providing a composite variable boundary layer; or making a substantially fully dense part by compaction forging.

Therefore, there is a need for a composite powder metal variable boundary part exhibiting improved impact resistance and bending fatigue resistance in the tooth root. It would also be advantageous to provide a composite variable boundary layer or a substantially fully dense part by compaction forging. There is also a need for a method of producing a variable boundary in a composite powder metal part.

SUMMARY OF THE INVENTION

In accordance with the above-mentioned needs, a variable boundary composite powder metal gear exhibiting greater tooth wear resistance on its surface and greater impact resistance in its core is disclosed. The forged composite gear includes a plurality of teeth extending from a core, a first section having a first powder metal material, a second section having a second powder metal material and a variable boundary profile. The variable boundary profile is formed between the first section and the second section, whereby the variable boundary profile provides for greater tooth wear resistance on the teeth and greater impact resistance in the gear core.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of this invention, reference should now be made to the inventive aspects illustrated in greater detail in the accompanying drawings and described below.

FIG. 1 shows a partial cross-sectional view of a case carburized gear according to the prior art.

FIG. 2 shows an isometric view of a composite preform made after compacting and sintering required to obtain the inventive product after forging in accordance with an embodiment of the invention.

FIG. 3 shows a partial cross-sectional view of the composite preform of FIG. 2 having a composite material.

FIG. 4 shows an isometric view of a differential side gear made from the composite preform of FIG. 2 in accordance with an embodiment of the invention.

FIG. 5 shows a partial-cross sectional view of the differential side gear shown in FIG. 4.

FIG. 6 shows a partial cross-sectional view of the differential side gear shown in FIG. 5.

FIG. 7 shows a schematic layout of an embodiment of a process according to the invention to obtain a composite powder metal variable boundary part.

DETAILED DESCRIPTION

In all figures, the same reference numerals are used to identify like parts in the various views. Thus, simultaneous reference to the various figures is appropriate. In some instances, for clarity, equivalent parts in different figures may have different reference numbers.

FIG. 2 shows an isometric view of a composite preform 84 made after compacting and sintering required to obtain the inventive product after forging in accordance with an embodiment of the invention.

FIG. 3 shows a partial cross-sectional view of the composite preform 84 of FIG. 2 having a composite material. The preform 84 includes a first powder metal material 55 and a second powder metal material 57 separated by material boundary 59. The material boundary 59 is representative of the boundary between at least two materials obtained after a compacting process of strategically filled or placed powder metals into a compaction die. While the material boundary 59 is shown as a precise demarcation between the different materials 55, 57, the actual material boundary line will approximate the separation of the materials depending upon the filling process used to create the composite preform. The art of filling a compaction die with different powder metals to obtain a composite preform is known to those skilled in the art, but is only briefly introduced for an understanding of the invention presented herein.

FIG. 4 shows an isometric view of a differential side gear 50 made from the composite preform 84 of FIG. 2 in accordance with an embodiment of the invention. The differential side gear 50 includes plurality of teeth 52 having a variable boundary profile 58 as shown in FIG. 6 and described herein. Each tooth of the plurality of teeth 52 has a first surface 54 and a tooth core or root 56. The differential side gear 50 has a rotational axis 60, wherein the teeth 52 extend radially outward in the same general direction as the rotational axis of the gear, but are inclined with respect to the rotational axis. The differential side gear 50 further includes an axially splined internal section 62 axially aligned with the rotational axis 60. The differential side gear 50 is made by compaction forging the composite preform 84.

FIG. 5 shows a partial-cross sectional view of the differential side gear 50 shown in FIG. 4. The differential side gear 50 after forging results in a first section 51 made from a first powder metal material 55, and second section 53 made from a second powder metal material 57. Also, the gear 50 includes a variable boundary profile 58 as shown in FIG. 6. The variable boundary profile 58 exhibits the performance properties mentioned above, while not necessarily being formed from a carburized zone, but being formed from the material boundary 59 created by the forging of the composite materials 55, 57. The variable boundary profile 58 in the gear exhibits improved tooth wear resistance or loading on the plurality of teeth 52 and improved impact or bending resistance in the gear core 56. Also, the second powder metal material 57 may be chosen advantageously to obtain preferential performance properties for the splines 62 of the gear 50 while advantageously maintaining the performance properties desired at the teeth 52.

Optionally, a composite material may be strategically utilized for each material section. Also, additional or multiple material sections may be utilized in a preform in order to obtain multiple composite variable boundary profiles on select portions of a final forged part or gear, thereby obtaining select performance features.

FIG. 6 shows a partial cross-sectional view of the differential side gear 50 shown in FIG. 5. The differential side gear 50 includes a composite variable boundary profile 58. The variable boundary profile 58 may be coincidental with the material boundary 59 in a particular cross-sectional view, such as that represented in FIG. 5, but the material boundary 59 is not determinative of the variable boundary profile 58 as shown in FIG. 6.

The first surface 54 of the gear 50 includes a tip surface 64, a pitch line surface 66, a root fillet surface 68 and a root diameter or land surface 70. The variable boundary profile 58 is substantially represented by the effective boundary of: 2.4 mm at the tip surface; 1.9 mm at the pitch line surface; 0.4 mm at the root fillet surface; and 0.8 mm at the root land surface. While specific numbers are presented in the present embodiment, it is recognized that the variable boundary profile may have any non-constant effective boundary profile over a particular surface cross-section and is not limited to the specific profile here presented and is not intended to be limited by the example here given.

The variable boundary profile 58 may also be represented by a boundary ratio. The effective boundary ratio is given by comparing boundary depths measured at the tip surface 64 to the root fillet surface 68, the pitch line surface 66 to the root fillet surface 68, or the root land surface 70 to the root fillet surface 68. For example, the variable boundary ratio for the tip surface 64 to the root fillet surface 68 is 6:1, the pitch line surface 66 to the root fillet surface 68 is 19:4, and the root land surface 70 to the root fillet surface 68 is 2:1.

Advantageously, the boundary ratio may be 6:1 over the variable boundary profile 58 from the greatest depth to the shallower depth, thereby achieving greater mechanical properties such as tooth wear and impact resistance as desired.

Moreover, it is desirable to select a first powder metal material 55 for the first surface 54 of the teeth 52 achieving a surface hardness of at least 58 HRC in the forged gear. It also may be desirable to have a second powder metal material 57 in the gear core 56 having a hardness of not more than 43 HRC. In this regard, the second powder metal material is selected having effectively a non-hardening material such a low ferrous alloy steel having less than 0.2% carbon and the first powder metal material is a hardening material made from a different ferrous steel having a higher carbon content.

The variable boundary profile 58 advantageously provides a gear having greater tooth wear resistance on the first surface 54 while providing impact resistance in the tooth root 56 or improved shear resistance in the spline 62. The variable boundary profile 58 is representative of the effective boundary profile achieved by strategic compaction forging of a preform. The variable boundary profile 58 resultantly achieved by the forging process as discussed herein.

While the process is described with respect to a differential side gear 50, it is anticipated that the variable boundary profile 58 may be achieved on other parts or gears, including bevel, differential or pinion gears, without limitation.

The differential side gear 50 may be made from a low alloy, fully compacted, ferrous powder metal material for one of the material portions. However, it is anticipated that the gear may be made of various other types of forged powder metal steels.

Turning to the method of making the inventive variable boundary powder metal gear 50, FIG. 7 shows a schematic layout of an embodiment of a process according to the invention to obtain a composite powder metal variable boundary part. The process begins with step of mixing 219, 220, wherein each material is prepared for filling into a compaction form. Then the process continues with the step of filling 221, 222, wherein each material is strategically placed into the compaction form. Then after the filling step is completed the process continues with the steps of compacting 224, sintering 226, forging 232, and cooling 234. Post forging operations (not shown) may also be used to further enhance the gear. For brevity, and because some of these process steps are known to those in the art of forging powder metals, only certain aspects of the inventive process are discussed below. In this regard, material selection, temperature processing and compaction pressures are discussed only briefly.

The mixing step 219, 220 readies each metal powder, including any needed binders or lubricants, by mixing the material until a nearly uniform mixture is achieved ready for filling into a compacting form during the filling step 221, 222. An optional step of separating 223 may be included during the filling steps 221, 222 thereby facilitating the material placement into the compaction form. While two mixing steps 219 and 220, and two filling steps 221 and 222 are shown, it is recognized that additional mixing or filling are necessary for each additional material desired. The filling steps 221, 222 can be sequentially such that the material 55 for the first surface 54 is strategically placed in the preform prior to the material 57 for the second surface 56, for example. In some cases, however, the filling steps 221, 222 may be simultaneous or nearly simultaneous.

The compacting step 224 includes the compaction of at least two different powder metal materials in a compaction form to obtain a preform. Before compacting, filling of a first portion of the compaction form with a first powdered metal material, then, with optional use of a separator 223, filling a second portion of the compaction form with a second powdered metal material. After the filling step of the die cavity is complete, the composite metal powders are compacted within the die cavity to form a preform. The preform includes at least one cross-sectional surface in which the final forged part resultantly obtains a variable boundary profile, as discussed herein. The process is then completed by sintering, forging and cooling steps to achieve a gear having a first section having the first powder metal material and a second section having the second powder metal material. It is noted that the first and second portions in the filling stage resulting in a preform, do not necessarily achieve the same boundary as a first and second sections of the final product.

The sintering step 226 may be accomplished as is known by a person of skill in the art. Optionally, if one of the composite materials is conducive to carburization or “sint-carb” processing, as is know in the art, then the material may include a carburization step to achiever further beneficial results prior to the forging process.

The variable forging or forging step 232 comprises forging the preform at a forge temperature and a forge pressure to obtain a substantially dense, net shape, part. The variable boundary profile for the gear results in nearly symmetrical profiles for each tooth because of the symmetrical nature of the forging process and the symmetrical nature of the preform. However, it is recognized that optional carburization steps or additional forging steps may be used to obtain multiple variable boundary profiles. The variable boundary profile is achieved by utilizing a die set of the forge to variably enhance critical flow of the different metal portions during the forging process. Essentially, the determined boundary of the composite powder metal preform is strategically compressed into the die sections, wherein portions of the preform are stretched and thinned during forging and other portions of the preform are thickened and deepened achieving the different powder metal zones from the composite preform.

In one aspect, the forging step used to obtain the composite variable boundary profile is further enhanced by strategically forming the material boundary layer in the preform to enhance critical flow of the composite powder metal preform during the forging process.

The cooling step 234 allows the forged part to obtain a particular metallurgy resulting in a gear having the desired variable boundary profile. Cooling of the forged part may be by quenching in oil, water, air or by other methods suitable to the powder metal forging process.

Prior to cooling, an optional dwelling step may be included, allowing the forged part to dwell for a period allowing for enhanced properties by allowing the material temperature to stabilize in the part.

Optionally, a preheating step may be included wherein the preform is heated to a pre-forge temperature prior to forging to enhance the desired metal flow during the forging process.

Further, optional post forging operations may include, turning, facing, surface grinding, splining, and broaching of the product depending upon final specification requirements, thereby being ready for washing, packing, or shipping. Because of the multi-material work piece, the finish class of these steps can be improved. For example, a higher spline class is achievable for the spline 62 of FIG. 4 because of the non-hardened second material 57. This improves the entire machining system by improving the spline class, yet reducing tool wear.

With proper selection and combinations of powder metal, compaction forms, processing times, processing temperatures, processing pressures, forging dies, and cooling method a near-net shape, fully dense product may be obtained having the variable boundary profile, thereby requiring minimal if any machining operations facilitating cost savings and performance improvements.

While various process steps have been presented, they are intended only to be limited in scope or order as indicated in the claims of this invention. Further, while the invention has been described in connection with several embodiments, it should be understood that the invention is not limited to those embodiments. Thus, the invention covers all alternatives, modifications, and equivalents as may be included in the spirit and scope of the appended claims. 

1. A forged composite gear comprising: a core substantially comprising a first powder metal material; a plurality of teeth extending from said core and at least partially comprising a second powder metal material; and a variable boundary profile formed between said first powder metal material and said second powder metal material, wherein said first powder metal material exhibits greater impact resistance and said second powder metal material exhibits greater wear resistance.
 2. The forged gear according to claim 1 wherein said second powder metal material has a surface hardness of at least 58 HRC.
 3. The forged gear according to claim 1 wherein said first powder metal material has a hardness of less than 43 HRC.
 4. The forged gear according to claim 1 wherein said first powder metal material is a non-hardening material and said second powder metal material is a hardening material.
 5. The forged gear according to claim 4 wherein said variable boundary profile is forged in said plurality of teeth.
 6. The forged gear according to claim 1 wherein said first powder metal material has substantially lower carbon content than said second powder metal material.
 7. The forged gear of claim 1 wherein said gear is a bevel gear, said bevel gear having a rotational axis, said plurality of teeth extending radially in the same general direction as the rotational axis of said bevel gear, but inclined with respect to the rotational axis of said bevel gear.
 8. The bevel gear of claim 7 wherein said bevel gear is a differential side gear having an axially splined internal section in said core.
 9. The forged gear of claim 1 wherein each tooth of said plurality of teeth comprise a first surface comprising a tip surface, a pitch line surface, a root fillet surface and a root land surface, wherein said variable boundary profile is substantially represented by a boundary ratio satisfied by at least one of a root land surface to a root fillet surface of approximately 2:1, a tip surface to said root fillet surface of approximately 6:1, or a pitch line surface to said root fillet surface of approximately 19:4.
 10. A bevel gear comprising: a gear core defining a rotational axis; a plurality of radial teeth extending from said gear core and extending in the same general direction as said rotational axis of said gear core, but inclined with respect to said rotational axis of said gear core; a first powder metal material at least partially forming said plurality of radial teeth; and a second powder metal material forming said gear core and partly forming a core of said plurality of radial teeth, said first and said second powder metal materials being sintered and forged to form a variable boundary profile between said first and second powder metal materials, the first and second powder metal materials having different hardness properties.
 11. The bevel gear according to claim 10 wherein said bevel gear is a pinion gear having an axial internal section in said gear core.
 12. The bevel gear according to claim 10 wherein said first powder metal material comprises a surface hardness of at least 58 HRC.
 13. The bevel gear according to claim 10 wherein said second powder metal material comprises a hardness of not more than 43 HRC.
 14. The bevel gear according to claim 10 wherein said first powder metal material is a hardening material and said second powder metal material is effectively a non-hardening material.
 15. The bevel gear according to claim 10 wherein said second powder metal material has substantially lower carbon content than said first powder metal material.
 16. A method of forming a gear from at least two different powder metal materials comprising the sequential steps of: preforming at least two different powder metal materials into a preform comprising the steps of: filling a first portion of a compaction form with a first powder metal material, said compaction form shape corresponding to the shape of said preform; filling a second portion of said compaction form with a second powder metal material; and compacting said powders in said compaction form to form said preform; sintering said preform; forging said preform at a forge temperature and a forge pressure to obtain a substantially dense, net shape, forged part having a first section having said first powder metal material and a second section having said second powder metal material, and a boundary profile formed there between; and cooling said forged part.
 17. The method of claim 16 wherein preforming further comprises separating during filling by inserting a separator into said compaction form for filling one of said powder metal materials, and removing said separator from said compaction form prior to compacting.
 18. The method of claim 16 wherein said boundary profile is a variable boundary profile.
 19. A bevel gear having a gear core, a rotational axis, a plurality of radial teeth core and a plurality of radial teeth, said radial teeth extending in the same general direction as the rotational axis of said bevel gear, but inclined with respect to the rotational axis of said bevel gear, produced in accordance with the process of claim 16, wherein said first section substantially forms an exterior surface of said plurality of radial teeth, and said second section forms said gear core and a core of said plurality of radial teeth.
 20. The bevel gear of claim 19 wherein each tooth of said plurality of teeth comprises a first surface comprising a tip surface, a pitch line surface, a root fillet surface and a root land surface, wherein said boundary profile is a variable boundary profile and is substantially represented by a boundary ratio satisfied by at least one of a root land surface to a root fillet surface of approximately 2:1, a tip surface to said root fillet surface of approximately 6:1, or a pitch line surface to said root fillet surface of approximately 19:4.
 21. The method of claim 16 wherein said first and second powder metal materials are different low alloy ferrous materials. 